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| United States Patent |
5,208,546
|
|
Nagaraj
, et al.
|
May 4, 1993
|
Adaptive charge pump for phase-locked loops
Abstract
A method and apparatus for improving the performance of a phase-locked loop
are disclosed. A phase error between two signals is sensed and a temporary
increase in the bandwidth of the phase-locked loop is provided responsive
to the sensed phase error. The phase-locked loop may comprise a charge
pump and the temporary increase in the bandwidth of the phase-locked loop
may comprise a temporary increase in charge pump current. An increase in
phase-locked loop bandwidth is followed by a decrease in the bandwidth
responsive to a decrease in phase error. The decrease in bandwidth may
comprise a decrease in charge pump current.
| Inventors:
|
Nagaraj; Krishnaswamy (Macungie, PA);
Shariatdoust; Reza S. (Spotswood, NJ)
|
| Assignee:
|
AT&T Bell Laboratories (Murray Hill, NJ)
|
| Appl. No.:
|
748136 |
| Filed:
|
August 21, 1991 |
| Current U.S. Class: |
327/157; 327/244; 331/1A; 331/17; 331/25 |
| Intern'l Class: |
H03K 017/00; H03L 007/00 |
| Field of Search: |
328/155
307/262,269
331/1 A,17,25
|
References Cited
U.S. Patent Documents
| 3610954 | Oct., 1971 | Treadway | 328/133.
|
| 4524333 | Jun., 1985 | Iwata et al. | 328/155.
|
| 4885554 | Dec., 1989 | Wimmer | 328/155.
|
| 4890072 | Dec., 1989 | Espe et al. | 328/155.
|
| 4920320 | Apr., 1990 | Matthews | 328/155.
|
Other References
F. M. Gardener, Phaselock Techniques, 123-25 (1979).
|
Primary Examiner: Callahan; Timothy P.
Attorney, Agent or Firm: Restaino; Thomas A.
Claims
We claim:
1. In a phase-locked loop including a loop filter, an oscillator providing
an output of the phase-locked loop, a phase detector, and a charge pump
providing current to the loop filter, the current having a magnitude, a
method of adjusting the bandwidth of the phase-locked loop, the method
comprising the steps of:
the phase detector sensing a phase error between a reference signal and the
output signal of the phase-locked loop;
the charge pump increasing the magnitude of charge pump current responsive
to the phase error sensed by the phase detector and providing the charge
pump current to the loop filter; and
subsequent to increasing the magnitude of said current, the charge pump
decreasing the magnitude of said current.
2. The method of the claim 1 wherein the charge pump increases and
decreases the magnitude of the charge pump current by the same amount.
3. The method of claim 1 wherein the step of the charge pump decreasing the
magnitude of the charge pump current is performed in response to a
decrease in sensed phase error by the phase detector.
4. In a phase-locked loop including a loop filter, an oscillator, and a
phase detector for detecting errors between a reference signal and an
output signal of the loop, an adaptive charge pump for coupling to the
phase detector and the loop filter in the phase-locked loop and for
providing charge pump current to the loop filter, the charge pump current
having a magnitude, the adaptive charge pump comprising:
a. a variation sensor for determining when the magnitude of charge pump
current provided to the loop filter should be increased, the determination
to increase the magnitude of charge pump current based upon a phase error
detected by the phase detector; and
b. a variable current source, coupled with the variation sensor, for
providing charge pump current to the loop filter and for providing
1. an increase in the magnitude of charge pump current responsive to said
determination by the variation sensor, and
2. subsequent to providing said increase, a decrease in the magnitude of
charge pump current.
5. The adaptive charge pump of claim 4 wherein the increase and decrease in
the magnitude of charge pump current are equal.
6. The adaptive charge pump of claim 4 wherein the variable current source
provides a decrease in the magnitude of charge pump current responsive to
a decrease in phase error detected by the phase detector.
7. The adaptive charge pump of claim 4 wherein the variation sensor
comprises:
a capacitor;
first current source means for producing a first current for use in
charging the capacitor, said first current being provided responsive to a
phase error detected by said phase detector;
second current source means for producing a second current for use in
discharging the capacitor; and
means for determining when the magnitude of charge pump current should be
increased responsive to a voltage across the capacitor.
8. The adaptive charge pump of claim 7 wherein the magnitude of the first
current is substantially ten times the magnitude of the second current.
9. A phase-locked loop comprising:
a. a phase detector for sensing a phase error between a reference signal
and an output signal of the phase-locked loop;
b. a loop filter, the loop filter for receiving charge pump current having
a magnitude and for providing a filter output signal;
c. a variation sensor for determining when the magnitude of said charge
pump current received by the loop filter should be increased, the
determination to increase the magnitude of said charge pump current based
on a phase error sensed by the phase detector;
d. a variable charge pump current source for providing charge pump current
to the loop filter, and for providing
1. an increase in the magnitude of said charge pump current responsive to
said determination by the variation sensor, and
2. subsequent to providing said increase, a decrease in the magnitude of
said charge pump current; and
e. an oscillator for providing the phase-locked loop output signal
responsive to the filter output signal.
10. The phase-locked loop of claim 9 wherein the increase and decrease in
the magnitude of said charge pump current are equal.
11. The phase-locked loop of claim 9 wherein the variable current source
provides a decrease in the magnitude of said charge pump current
responsive to a decrease in phase error detected by the phase detector.
12. The phase-locked loop of claim 9 further comprising a divider circuit,
coupled between the phase detector and the oscillator, for dividing the
frequency of the phase-locked loop output signal by a predetermined
number.
13. The phase-locked loop of claim 12 further comprising a reference signal
divider circuit, coupled to the phase detector, for dividing the frequency
of the reference signal by a predetermined number.
14. The phase-locked loop of claim 13 wherein each of the divider circuits
is independently programmable to allow selection of the predetermined
number.
15. The phase-locked loop of claim 9 wherein the phase detector comprises a
phase-frequency detector.
Description
FIELD OF THE INVENTION
The present invention relates generally to phase-locked loops and more
specifically to charge pumps for phase-locked loops.
BACKGROUND OF THE INVENTION
A basic phase-locked loop (PLL) is a circuit which produces an output
signal synchronized to an input reference signal. A PLL output signal is
synchronized or "locked" to a reference signal when the frequency of the
output signal is the same as that of the reference signal. Under locked
conditions, a PLL may provide for a constant phase difference between the
reference and output signals. This phase difference may assume any desired
value including zero. Should a deviation in the desired phase difference
of such signals develop (i.e., should a phase error develop) due to, e.g.,
variation in either (i) the frequency of the reference signal or (ii)
programmable parameters of the PLL, the PLL will attempt to adjust the
frequency of its output signal to drive the phase error toward zero.
There are several different types of PLLs. Among these are PLLs which are
charge pump-based. In a charge pump-based PLL, a phase-frequency detector
compares an input reference signal to an output signal from a voltage
controlled oscillator for the purpose of observing phase and frequency
differences between the signals. If differences are observed, the
phase-frequency detector produces logic pulses indicative of such
differences. A charge pump receives these logic pulses and, based thereon,
provides pulses of current to a loop filter and ultimately the voltage
controlled oscillator. As filtered, these current pulses serve to adjust
the voltage controlled oscillator to compensate for the observed
differences.
The magnitude of PLL bandwidth is a parameter affecting PLL performance.
The larger the bandwidth, the larger the steady-state phase jitter (i.e.,
the larger the phase error due to circuit noise) of the PLL but the
smaller the settling time for variations in the reference signal or PLL
parameters (i.e., the smaller the time needed by the PLL to adjust to the
variations). The smaller the PLL bandwidth, the smaller the steady-state
phase jitter, but the larger the settling time. Consequently, a PLL design
trade-off issue can exist between desirable values of steady-state phase
jitter and reference signal/PLL parameter variation settling time.
SUMMARY OF THE INVENTION
The present invention provides a method and apparatus for temporarily
providing an increased PLL bandwidth responsive to variations or
transients in a reference signal or programmable loop parameters, and a
narrow bandwidth during the steady-state.
An illustrative embodiment of the present invention comprises an adaptive
charge pump which operates to employ a relationship between the magnitude
of charge pump current and PLL bandwidth. This relationship provides that
increases in charge pump current tend to increase PLL bandwidth, while
decreases in current tend to decrease PLL bandwidth. The embodiment
provides for sensing the above-described variations and, responsive
thereto, temporarily increasing the magnitude of charge pump current. The
increased charge pump current increases PLL bandwidth and therefore
decreases settling time of a PLL in response to such variations. Once PLL
output signal phase has been modified to track the variations, the charge
pump current is reduced, reducing PLL bandwidth and steady-state phase
jitter. The temporary nature of an increase in charge pump current
provides for enhanced PLL settling properties, as needed, without a
sustained increase in PLL steady-state phase jitter.
The illustrative embodiment of the present invention functions by operation
of a variation sensor in combination with a variable current source. The
variation sensor monitors the outputs of a PLL's phase-frequency detector
for the presence of logic pulses indicating a variation to be tracked.
Responsive to sensing significant logic pulses, the variation sensor
signals the variable current source that increased current should be
provided to the loop filter and VCO of the PLL to improve settling time.
The variable current source responds by increasing the magnitude of its
output current pulses, thereby increasing PLL bandwidth and providing for
quicker adjustment to the sensed variation.
Once the voltage controlled oscillator of the PLL responds to the filtered
current pulses by adjusting its output to track the variation, significant
logic pulses from the phase-frequency detector cease. The variation sensor
responds to the lack of significant logic pulses by de-asserting its
signal to the variable current source, which, in response, reduces the
magnitude of current pulses it produces.
The present invention has use in many systems such as clock signal
synthesizer systems for, among other things, video graphics applications.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 presents an illustrative charge pump-based phase-locked loop.
FIG. 2 presents an illustrative embodiment of the adaptive charge pump of
the present invention.
FIG. 3 presents an illustrative variation sensor.
FIG. 4 presents an illustrative variable current source.
DETAILED DESCRIPTION
Introduction
An illustrative charge pump-based phase-locked loop (PLL) 50 is presented
in FIG. 1. A reference signal U.sub.I is received by a digital
programmable divider circuit 75, which divides the frequency of U.sub.I by
a programmable value N. A resulting signal, U.sub.IN, is provided to a
phase-frequency detector (PFD) 100. Also provided to the PFD 100 is signal
U.sub.OM, which is the output of a voltage controlled oscillator (VCO)
400, U.sub.O, divided by a number M by another digital programmable
divider circuit 500. PFD 100 detects differences in phase and frequency
between U.sub.IN and U.sub.OM, and provides logic signals to an embodiment
of an adaptive charge pump 200 indicating when such differences have been
detected. By arbitrary convention these logic signals are designated as
DOWN and UP, respectively. (It will be apparent to one of ordinary skill
in the art that the opposite convention could be chosen.)
The adaptive charge pump 200 is coupled to a loop filter 300 and provides a
charge pump output current, I.sub.CO, to the loop filter 300 based on the
received UP/DOWN logic signals. The loop filter 300 provides low-pass
filtering to I.sub.CO, yielding a filtered signal U.sub.F. This signal is
provided as feed-back to the VCO 400.
The digital programmable dividers 75 and 500 in the illustrative embodiment
may be any of those well known in the art. The illustrative PFD 100 may be
any of the well-known types, such as that presented in FIG. 6.18 in F. M.
Gardener, Phaselock Techniques, 123-25 (1979). The loop filter 300 of the
illustrative embodiment is a first order low-pass filter. The illustrative
VCO 400 comprises a voltage to current converter coupled to a ring
oscillator which comprises three current controlled inverters.
The Adaptive Charge Pump
The illustrative embodiment of the adaptive charge pump 200 is presented in
FIG. 2. UP/DOWN logic signals from PFD 100 are provided to both a
variation sensor (VS) 220 and a variable current source (VCS) 260. The VS
220 is coupled to VCS 260, and both are coupled to a power supply voltage,
V.sub.DD. Responsive to detecting significant UP/DOWN logic signals from
the phase-frequency detector 100, the VS 220 sends a variation signal,
U'.sub.VS, to the VCS 260. The VCS 260 provides output current I.sub.CO to
the loop filter 300 of the PLL 50.
The Variation Sensor
An illustrative VS 220 is presented in FIG. 3. As shown in the Figure, the
UP/DOWN logic signals from the PFD 100 are logically ORed by gate 225 to
form signal S.sub.1. Signal S.sub.1 controls the operation of a switch
229, which in turn modulates the flow of current, I.sub.1, from current
source 227. Switch 229 will close during the intervals when signal S.sub.1
is logically true. Resistor 235 is coupled to switch 229 at node A, along
with current source 233. Capacitor 231 is coupled to resistor 235 at node
B.
Current source 233 provides a current I.sub.2 which is related to current
I.sub.1 as follows:
##EQU1##
where n is, for example, 10. The value of n determines the average duty
cycle of S.sub.1 deemed to be significant so as to cause an increase in
VCS 260 output current. For example, for I.sub.1 =20 .mu.A and I.sub.2 =2
.mu.A (n=10), UP/DOWN logic pulses causing a duty cycle for S.sub.1 >0.1
(i.e., greater than 10 percent) will be deemed significant for purposes of
variation sensing. (see, section entitled Operation of the Illustrative
Embodiment).
The voltage signal at node B is designated as U.sub.VS. This signal is
received by inverter 237 which provides as output a logical TRUE signal
whenever it receives an input signal which is less than or equal to a
threshold, V.sub.th. Inverter 237 will provide as output a logical FALSE
signal whenever it receives an input signal which is greater than
V.sub.th. Because of this threshold, the inverted signal output from
inverter 237 is indicated with a "prime" notation: U'.sub.VS. This output
is again inverted by inverter 239 to provide signal U'.sub.VS. It is this
signal, U'.sub.VS, which is output to the VCS 260.
The Variable Current Source
An illustrative variable current source 260 is presented in FIG. 4. As
shown in the Figure, the VCS 260 includes two current sources, 265 and
275, which are directly modulated by the UP and DOWN logic pulse signals
from the PFD 100 by operation of switches 290 and 292, respectively. VCS
260 also includes two current sources 270 and 280 which are modulated not
only by the UP and DOWN logic pulse signals applied to switches 290 and
292, respectively, but also by signal U'.sub.VS, by operation of switches
285 and 287, respectively. Exemplary values for I.sub.3 and I.sub.4 are 4
.mu.A and 20 .mu.A, respectively.
When signal U'.sub.VS is logically FALSE, the output current of the VCS
260, I.sub.CO, may comprise current from either of sources 265 or 275,
depending on the presence or absence of UP or DOWN logic pulse signals
controlling switches 290 or 292, respectively. However, when signal
U'.sub.VS is logically TRUE, the output current of the VCS 260 may
comprise current from either of sources 265 or 275, depending on the
presence or absence of UP or DOWN logic pulse signals, plus current from
either source 270 or 280.
In light of the above, it will be understood by one of ordinary skill in
the art that current sources controlled by switches in the VCS 260 and the
VS 220 may comprise separate switches and sources, as presented in FIGS. 3
and 4, or unified switched current sources. Whether separate or together
as a single element, such may be formed with field effect transistors
using techniques well known in the art.
Operation of the Illustrative Embodiment
Under steady-state (e.g., locked) conditions, the UP/DOWN logic signals
from PFD 100 are infrequent and of short duration, if present at all. As a
result, the duty cycle, DS, of signal S.sub.1 from OR gate 225 is very
small or zero (e.g., less than 10 percent). Switch 229 will therefore
remain open most of the time and current source 227 will be largely
blocked. (Under steady-state conditions, some conventional PFDs provide
narrow UP/DOWN spikes from time to time; as will be appreciated by the
ordinary artisan, these spikes will not affect the fundamental operation
of this embodiment.) At the same time, current source 233 is working to
pull charge from capacitor 231 via resistor 235 at a rate of I.sub.2
=I.sub.1 /n. Since I.sub.2 >I.sub.1 .times.DS, the voltage across the
capacitor, U.sub.VS, is driven toward zero. The condition of U.sub.VS
.ltoreq.V.sub.th is sensed by the threshold logic of inverter 237, causing
it to output a logical TRUE signal. In response, inverter 239 provides a
logical FALSE signal, U'.sub.VS, to switches 285 and 287 of VCS 260. This
FALSE signal causes the switches to open (or allows them to remain open).
VCS 260 output current, I.sub.CO, is therefore equal to I.sub.3, as
provided by current source 265 or 275, when switch 290 or 292,
respectively, is closed.
As a result of significant variations in the reference signal U.sub.I, or
in the programmable values of M and N (e.g., resulting in loss of lock),
significant UP/DOWN logic pulse signals are produced. Accordingly, the
duty cycle, DS, of signal S.sub.1 is large (e.g., greater than 10
percent). Switch 229 will close whenever signal S.sub.1 is TRUE. Each time
switch 229 closes, current I.sub.1 is allowed to flow and, as a result,
charge is deposited on capacitor 231. If the current I.sub.1 .times.DS
(the rate at which charge is being deposited on the capacitor) exceeds the
current I.sub.2 (the rate at which charge is being drained from the
capacitor), the voltage at node B, U.sub.VS, will be driven toward the
supply voltage, V.sub.DD. The condition of U.sub.VS >V.sub.th is sensed by
the threshold logic of inverter 237, causing inverter 237 to output a
logical FALSE signal. In response, inverter 239 provides a logical TRUE
signal, U'.sub.VS, to switches 285 and 287 which close in response. During
the time when switches 285 and 287 are closed and UP/DOWN pulses are
present, VCS 260 output current, I.sub.CO, is equal to I.sub.3, as
provided by current source 265 or 275, plus I.sub.4, as provided by
current source 270 or 280. Responsive to increased output current,
I.sub.CO, the bandwidth of the PLL 50 is increased thus enhancing its
variation settling properties.
As a result of the VCO 400 adjusting its output signal to reduce the PLL 50
phase error (between signal U.sub.IN and output signal U.sub.OM) to a
small, if not zero, level, the PFD 100 will cease generating significant
UP/DOWN logic pulses. Absent such significant logic pulses, the voltage at
node B of the VCS 260, U.sub.VS, is driven toward zero by current source
233. The condition of U.sub.VS .gtoreq.V.sub.th is sensed by the threshold
logic of inverter 237 causing it to provide a logical TRUE signal as
output. This signal is inverted by inverter 239 to a logical FALSE signal
causing switches 285 and 287 to open. As a result, VCS 260 may provide
output current equal to I.sub.3 from sources 265 and 275, depending on the
presence of UP/DOWN logic pulses at switches 290 and 292, respectively.
Responsive to this level of output current, the PLL 50 exhibits a reduced
level of phase jitter compared with that exhibited by the PLL 50 when its
output current equals the sum of I.sub.3 and I.sub.4.
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